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JP4922747B2 - Charged particle beam equipment - Google Patents

Charged particle beam equipment Download PDF

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JP4922747B2
JP4922747B2 JP2006341754A JP2006341754A JP4922747B2 JP 4922747 B2 JP4922747 B2 JP 4922747B2 JP 2006341754 A JP2006341754 A JP 2006341754A JP 2006341754 A JP2006341754 A JP 2006341754A JP 4922747 B2 JP4922747 B2 JP 4922747B2
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deflector
deflection
charged particle
lens
particle beam
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JP2008153131A (en
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和也 後藤
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Jeol Ltd
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    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01JELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
    • H01J37/00Discharge tubes with provision for introducing objects or material to be exposed to the discharge, e.g. for the purpose of examination or processing thereof
    • H01J37/02Details
    • H01J37/04Arrangements of electrodes and associated parts for generating or controlling the discharge, e.g. electron-optical arrangement or ion-optical arrangement
    • H01J37/153Electron-optical or ion-optical arrangements for the correction of image defects, e.g. stigmators
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B82NANOTECHNOLOGY
    • B82YSPECIFIC USES OR APPLICATIONS OF NANOSTRUCTURES; MEASUREMENT OR ANALYSIS OF NANOSTRUCTURES; MANUFACTURE OR TREATMENT OF NANOSTRUCTURES
    • B82Y10/00Nanotechnology for information processing, storage or transmission, e.g. quantum computing or single electron logic
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B82NANOTECHNOLOGY
    • B82YSPECIFIC USES OR APPLICATIONS OF NANOSTRUCTURES; MEASUREMENT OR ANALYSIS OF NANOSTRUCTURES; MANUFACTURE OR TREATMENT OF NANOSTRUCTURES
    • B82Y40/00Manufacture or treatment of nanostructures
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01JELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
    • H01J37/00Discharge tubes with provision for introducing objects or material to be exposed to the discharge, e.g. for the purpose of examination or processing thereof
    • H01J37/02Details
    • H01J37/04Arrangements of electrodes and associated parts for generating or controlling the discharge, e.g. electron-optical arrangement or ion-optical arrangement
    • H01J37/10Lenses
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01JELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
    • H01J37/00Discharge tubes with provision for introducing objects or material to be exposed to the discharge, e.g. for the purpose of examination or processing thereof
    • H01J37/02Details
    • H01J37/04Arrangements of electrodes and associated parts for generating or controlling the discharge, e.g. electron-optical arrangement or ion-optical arrangement
    • H01J37/147Arrangements for directing or deflecting the discharge along a desired path
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01JELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
    • H01J37/00Discharge tubes with provision for introducing objects or material to be exposed to the discharge, e.g. for the purpose of examination or processing thereof
    • H01J37/30Electron-beam or ion-beam tubes for localised treatment of objects
    • H01J37/317Electron-beam or ion-beam tubes for localised treatment of objects for changing properties of the objects or for applying thin layers thereon, e.g. for ion implantation
    • H01J37/3174Particle-beam lithography, e.g. electron beam lithography
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01JELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
    • H01J2237/00Discharge tubes exposing object to beam, e.g. for analysis treatment, etching, imaging
    • H01J2237/153Correcting image defects, e.g. stigmators
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01JELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
    • H01J2237/00Discharge tubes exposing object to beam, e.g. for analysis treatment, etching, imaging
    • H01J2237/26Electron or ion microscopes
    • H01J2237/28Scanning microscopes

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  • Chemical & Material Sciences (AREA)
  • Engineering & Computer Science (AREA)
  • Nanotechnology (AREA)
  • Analytical Chemistry (AREA)
  • Physics & Mathematics (AREA)
  • Crystallography & Structural Chemistry (AREA)
  • Theoretical Computer Science (AREA)
  • Mathematical Physics (AREA)
  • Condensed Matter Physics & Semiconductors (AREA)
  • General Physics & Mathematics (AREA)
  • Manufacturing & Machinery (AREA)
  • Electron Beam Exposure (AREA)
  • Exposure And Positioning Against Photoresist Photosensitive Materials (AREA)

Description

本発明は、荷電粒子ビームを集束・偏向し、そのビームで目標物を走査する電子光学装置であり、例えば電子ビーム描画装置や走査型電子顕微鏡を具体例とする荷電粒子ビーム装置に関する。   The present invention relates to an electron optical apparatus that focuses and deflects a charged particle beam and scans a target with the beam, and relates to a charged particle beam apparatus using, for example, an electron beam drawing apparatus or a scanning electron microscope.

荷電粒子ビーム装置、或いは荷電粒子ビーム集束偏向装置として知られる、従来型の電子ビーム集束偏向装置を図1に示す。各部位の相対的位置関係は、下記特許文献1に示されている光学系(電子ビーム描画装置)の光学系と同じである。縮小レンズ1により光源(物体)2の像3が形成され、対物レンズ4により像3の像5が材料6面上に形成される。この状態で偏向器7を働かせて電子ビーム9を偏向すれば、像5を所望の位置に移動させることができる。なお、縮小レンズ1の倍率(絶対値)は当然1より小さいが、これは、微細な断面の電子ビーム(像5)を材料6に照射するためである。図1の光学系を電子ビーム描画の目的で用いるのであれば、集積回路の微細パターンを描画するため、このことは必須である。また、同目的には、偏向速度を速くするため、偏向器7としては静電偏向器が用いられる。   FIG. 1 shows a conventional electron beam focusing / deflection device known as a charged particle beam device or a charged particle beam focusing / deflection device. The relative positional relationship of each part is the same as that of the optical system (electron beam drawing apparatus) shown in Patent Document 1 below. An image 3 of the light source (object) 2 is formed by the reduction lens 1, and an image 5 of the image 3 is formed on the surface of the material 6 by the objective lens 4. If the deflector 7 is operated in this state to deflect the electron beam 9, the image 5 can be moved to a desired position. The magnification (absolute value) of the reducing lens 1 is naturally smaller than 1, but this is because the material 6 is irradiated with an electron beam (image 5) having a fine cross section. If the optical system of FIG. 1 is used for the purpose of electron beam drawing, this is indispensable for drawing a fine pattern of an integrated circuit. For this purpose, an electrostatic deflector is used as the deflector 7 in order to increase the deflection speed.

図1に示すように、偏向器7に加え偏向器8を設け、偏向系を多段構成とすれば、偏向収差(例えば偏向コマ収差や偏向色収差)を補正しつつ像5を所望の位置に移動させることができる。このとき、偏向器7,偏向器8の作る偏向場(強さと向き)は、偏向器7,8に起因する偏向収差が互いに打ち消されるように選ばれる。図1に示すように、偏向器8が像3の近くにあり、かつ電極長が短ければ、偏向器7の偏向感度(材料6面上における像5の移動距離と偏向電圧との比)と偏向器8のそれとを比較すると、前者は高く、後者は低くなる。そのような場合、大まかに言って、偏向器7は材料面6上の偏向距離及び偏向の向きを支配的に決め、偏向器8は偏向器7に起因する収差を補正している。なお、偏向器8の偏向感度が低いことは、偏向器が物点(この場合は像3)に近いほど偏向による物点(像3)の仮想的な移動が小さくなることに対応する。   As shown in FIG. 1, if a deflector 8 is provided in addition to the deflector 7 and the deflection system has a multi-stage configuration, the image 5 is moved to a desired position while correcting deflection aberration (for example, deflection coma aberration and deflection chromatic aberration). Can be made. At this time, the deflection fields (strength and direction) created by the deflectors 7 and 8 are selected so that the deflection aberrations caused by the deflectors 7 and 8 cancel each other. As shown in FIG. 1, when the deflector 8 is close to the image 3 and the electrode length is short, the deflection sensitivity of the deflector 7 (ratio between the moving distance of the image 5 on the surface of the material 6 and the deflection voltage) and When compared with that of the deflector 8, the former is high and the latter is low. In such a case, roughly speaking, the deflector 7 dominantly determines the deflection distance and the deflection direction on the material surface 6, and the deflector 8 corrects the aberration caused by the deflector 7. The low deflection sensitivity of the deflector 8 corresponds to the fact that the virtual movement of the object point (image 3) due to deflection becomes smaller as the deflector is closer to the object point (image 3 in this case).

図1に示した偏向器8と偏向器7のように、連動される偏向器が2つであれば、自由度は2となる。このことは、像5の位置を決めることと、それと同時に1種類の偏向収差を補正することが可能なことに対応する。   If there are two interlocked deflectors, such as deflector 8 and deflector 7 shown in FIG. 1, the degree of freedom is two. This corresponds to determining the position of the image 5 and simultaneously correcting one type of deflection aberration.

なお、下記特許文献2及び非特許文献1には、連動させる偏向器を3つとすれば、自由度が3になり、像5の位置を決めることと、2種類の収差を補正することが可能になることが記載されている。   In Patent Document 2 and Non-Patent Document 1 below, if there are three interlocking deflectors, the degree of freedom becomes 3, and the position of the image 5 can be determined and two types of aberrations can be corrected. It is described that it becomes.

また、下記特許文献1には、連動させる偏向器が2つであっても、レンズ場や偏向場の分布を選べば、1種類の収差を補正したうえで別の収差を完全には補正できないが低減することが可能であると記載されている。
特公平2−34426号公報 特開昭54−82962号公報 T. Hosokawa, Optik, vol. 56, No. 1, pp.21-30 (1980)
Also, in Patent Document 1 below, even if there are two deflectors to be linked, if one lens aberration or deflection field distribution is selected, one aberration can be corrected and another aberration cannot be completely corrected. Is described as being possible to reduce.
JP-B-2-34426 JP 54-82962 A T. Hosokawa, Optik, vol. 56, No. 1, pp.21-30 (1980)

ところで、従来から荷電粒子ビーム装置では、荷電粒子を被ビーム照射物の表面上で偏向する際に、偏向に伴う収差が発生していた。偏向に伴う収差としては、像面湾曲収差、非点収差、歪収差、コマ収差、色収差がある。このうち、フォーカスのずれとして発生する像面湾曲収差、非点収差については、補正器による動的補正が可能である。また、位置ずれとして生じる偏向歪収差は、偏向信号に補正信号を重畳させることで補正できる。これらの収差補正は、例えば電子ビーム描画装置において既に一般的に行われていた。   Conventionally, in a charged particle beam apparatus, when the charged particles are deflected on the surface of the irradiated object, aberration associated with the deflection has occurred. Aberrations accompanying deflection include field curvature aberration, astigmatism, distortion aberration, coma aberration, and chromatic aberration. Of these, curvature of field aberration and astigmatism that occur as a focus shift can be dynamically corrected by a corrector. In addition, the deflection distortion occurring as a positional deviation can be corrected by superimposing a correction signal on the deflection signal. Such aberration correction has already been generally performed in, for example, an electron beam drawing apparatus.

例えば、フォトマスク生産用の電子ビーム描画装置にあっては、前記被描画材料の表面上には、矩形状のビームが照射される。偏向フィールドが例えば1mmである場合には、偏向収差が原因のぼけ、位置ずれは数十nmとなるが、前記コマ収差と色収差の補正を行えば、描画精度が大きく向上する。なお、ここでは、材料6に投影される図形は十分小さいものとし、図形の大きさに起因する誤差は考えていない。   For example, in an electron beam drawing apparatus for producing a photomask, a rectangular beam is irradiated on the surface of the drawing material. When the deflection field is 1 mm, for example, the blur due to the deflection aberration and the positional deviation are several tens of nm. However, if the coma aberration and the chromatic aberration are corrected, the drawing accuracy is greatly improved. Here, it is assumed that the figure projected onto the material 6 is sufficiently small, and no error due to the size of the figure is considered.

前述のように、像5の位置を決定しつつ偏向コマ収差と偏向色収差を同時に補正するためには、自由度3となるように3つの偏向器を連動させればよい。しかしながら、そのような光学系の設計に関する指針、すなわち偏向場やレンズ場の最適化に関する指針はこれまで示されていない。条件によっては、偏向電圧が高くなりすぎるなどの問題が生じる。偏向の大きさを変えずに偏向電圧を下げるためには、偏向器長を長くする、または偏向器内径を小さくするとよいが、通常、偏向器長を長くすることは空間的制約から困難であり、また偏向器内径を小さくすることは、偏向器内壁へのコンタミ付着・帯電の問題から避けたほうがよい。   As described above, in order to simultaneously correct the deflection coma aberration and the deflection chromatic aberration while determining the position of the image 5, three deflectors may be interlocked so as to have three degrees of freedom. However, no guidance on the design of such an optical system, that is, on the optimization of the deflection field and the lens field has been shown so far. Depending on the conditions, problems such as an excessively high deflection voltage may occur. In order to lower the deflection voltage without changing the deflection size, it is better to lengthen the deflector length or to reduce the inner diameter of the deflector. However, it is usually difficult to increase the deflector length due to space constraints. In addition, it is better to avoid reducing the inner diameter of the deflector because of contamination and charging problems on the inner wall of the deflector.

偏向器長を長くしたり偏向器内径を小さくすることなく偏向電圧を低く抑えられる荷電粒子ビーム装置は、本件出願人による特願2006−003523に開示されている。図2は荷電粒子ビーム装置の構成を説明するための図である。縮小レンズ1の前段に収差補正用偏向器8を配置し、レンズの集束作用を利用して電子ビーム9の偏向角を拡大する構成である。   Japanese Patent Application No. 2006-003523 by the applicant of the present application discloses a charged particle beam device that can suppress the deflection voltage low without increasing the length of the deflector or reducing the inner diameter of the deflector. FIG. 2 is a diagram for explaining the configuration of the charged particle beam apparatus. In this configuration, an aberration correcting deflector 8 is disposed in front of the reduction lens 1 and the deflection angle of the electron beam 9 is enlarged by utilizing the focusing action of the lens.

しかし、この荷電粒子ビーム装置によっても、偏向コマ収差と偏向色収差を同時に補正する場合は、全ての偏向器の偏向電圧が低く抑えられるとは限らない。1種類の偏向収差を補正する場合は、2段の偏向器を用い、位置決めと、位置決めに伴う収差の補正との2つの役割を、それぞれ別の偏向器に独立に担わせることができるが、2種類の偏向収差を同時に補正する場合は、3段の偏向器を用いるため、場合によっては、ある偏向器の位置決めあるいは収差補正の効果が、別の偏向器の位置決めあるいは収差補正の効果で打ち消されることがあるからである。   However, even when this charged particle beam apparatus corrects deflection coma aberration and deflection chromatic aberration at the same time, the deflection voltages of all deflectors are not necessarily kept low. When correcting one type of deflection aberration, two stages of deflectors can be used, and the two roles of positioning and correction of aberration accompanying positioning can be independently assigned to different deflectors. When correcting two types of deflection aberrations at the same time, since a three-stage deflector is used, in some cases, the effect of positioning or aberration correction of one deflector is canceled by the effect of positioning or aberration correction of another deflector. It is because it may be.

このような場合、必要な大きさの偏向を得るためには、打ち消された位置決め偏向量あるいは偏向収差補正量の分だけ(電子ビーム9の軌道が振り戻された分だけ)、各偏向器による偏向を大きくする、すなわち偏向電圧を高くする必要が生じる。さらには、大きな偏向により、大きく軌道が振り戻されることは、電子ビーム9の軌道がレンズの中心軸から、より長い距離に渡り、より大きく外れることであるから、その他の偏向収差(像面湾曲収差、非点収差、歪収差)が増大しうるという問題も発生する。したがって、このような手法を用いる場合でも、偏向コマ収差と偏向色収差を同時に補正する光学系を設計するに当たっては、その最適化の指針をより詳細に定める必要がある。   In such a case, in order to obtain a deflection of a necessary size, the amount of the positioning deflection or the amount of deflection aberration correction canceled (by the amount of the electron beam 9 trajectory turned back) depends on each deflector. It becomes necessary to increase the deflection, that is, to increase the deflection voltage. Furthermore, a large deflection of the trajectory due to a large deflection means that the trajectory of the electron beam 9 deviates more from the central axis of the lens over a longer distance, and therefore other deflection aberrations (field curvature). (Aberration, astigmatism, distortion) may increase. Therefore, even when such a method is used, in designing an optical system that simultaneously corrects deflection coma and deflection chromatic aberration, it is necessary to define optimization guidelines in more detail.

なお、前記特許文献1の光学系によれば、3つではなく2つの偏向器を連動させるだけでも、1種類の収差を補正した上で別の収差をサブミクロンレベル(偏向フィールド10mm時)に低減することができると記載されているが、完全に補正することはできない。過去においては偏向に伴うビームぼけがサブミクロンレベルに低減されていれば問題ないとみなされたが、現在の電子ビームリソグラフィーにおいては、要求される描画精度の高さから、ビームぼけは数nm以下に低減されること、さらに理想的には完全に除去されることが求められる。   According to the optical system of Patent Document 1, even if two deflectors instead of three are interlocked, one aberration is corrected and another aberration is reduced to the submicron level (when the deflection field is 10 mm). Although it is described that it can be reduced, it cannot be completely corrected. In the past, it was considered that there was no problem if the beam blur due to deflection was reduced to the sub-micron level. However, in the current electron beam lithography, the beam blur is less than several nanometers due to the required high drawing accuracy. Reduction, and ideally, complete removal is required.

本発明は、前記実情に鑑みてなされたものであり、電極内径を小さくしすぎることなく、また偏向電圧を高くしすぎることなく、対物レンズ像面におけるビーム入射位置を決定しつつ偏向コマ収差と偏向色収差を同時に補正することのできる荷電粒子ビーム装置の提供を目的とする。   The present invention has been made in view of the above circumstances, and it is possible to determine the deflection coma aberration while determining the beam incident position on the objective lens image plane without making the electrode inner diameter too small and without making the deflection voltage too high. An object of the present invention is to provide a charged particle beam apparatus capable of simultaneously correcting the deflection chromatic aberration.

本発明に係る荷電粒子ビーム装置は、前記課題を解決するために、荷電粒子ビームを発生する荷電粒子ビーム源と、前記荷電粒子ビーム源からの荷電粒子ビームの寸法を縮小する縮小レンズと、前記縮小レンズによって寸法が縮小された荷電粒子ビームを被ビーム照射物の表面に集束する対物レンズと、前記縮小レンズの前段或いは前記対物レンズの物面近傍に配置される第1の偏向器と、前記対物レンズのレンズ場に対し、自らの発生する偏向場の全てあるいはその一部が重なるように配置される第2の偏向器と、前記第2の偏向器の後段に配置される第3の偏向器とを備える。   In order to solve the above problems, a charged particle beam apparatus according to the present invention includes a charged particle beam source that generates a charged particle beam, a reduction lens that reduces the size of the charged particle beam from the charged particle beam source, An objective lens that focuses the charged particle beam, the size of which is reduced by the reduction lens, on the surface of the irradiated object; a first deflector that is arranged in front of the reduction lens or in the vicinity of the object surface of the objective lens; A second deflector arranged so that all or a part of the deflection field generated by itself overlaps the lens field of the objective lens, and a third deflector arranged after the second deflector. With a vessel.

前記第1の偏向器、第2の偏向器及び第3の偏向器の寸法、位置、偏向電圧を調整して偏向場の分布を選び、対物レンズの像面におけるビーム入射位置を決定しつつ各々の偏向器に起因する偏向コマ収差を互いに打ち消すと同時に、各々の偏向器に起因する偏向色収差を互いに打ち消すことが好ましい。   Each of the first deflector, the second deflector, and the third deflector is adjusted in size, position, and deflection voltage to select the distribution of the deflection field and determine the beam incident position on the image plane of the objective lens. It is preferable to cancel the deflection coma aberration caused by the respective deflectors at the same time as canceling the deflection coma aberration caused by the respective deflectors.

また、前記偏向コマ収差と偏向色収差が打ち消される条件を満たしつつ、前記第2の偏向器及び前記第3の偏向器に入力する偏向信号を同じにすることが好ましい。   Further, it is preferable that the deflection signals input to the second deflector and the third deflector are the same while satisfying the conditions for canceling the deflection coma aberration and the deflection chromatic aberration.

また、前記第3の偏向器の前記第2の偏向器に対する回転角(偏向電極の向き)θについて、L、Lを前記第1及び第2偏向器のコマ収差係数とし、C、Cを前記第1及び第2偏向器の色収差係数とし、L、Cを前記第3の偏向器の前記第2の偏向器に対する回転角を零にした状態で定義される第3の偏向器のコマ収差係数及び色収差係数とし、ui2とui3を、それぞれ前記第3の偏向器の前記第2の偏向器に対する回転角を零にした状態で、前記第2の偏向器、前記第3の偏向器に単位偏向電圧を印加したときの、前記対物レンズ像面におけるビーム入射位置(複素数)と定義し、さらにθ=arg((L−L)/(L−L))としたとき、0<θ<2arg(ui2/ui3)あるいは0>θ>2arg(ui2/ui3)の関係が成り立つように、レンズ場と偏向場の分布を選択することが好ましい。 Further, with respect to the rotation angle (direction of the deflection electrode) θ of the third deflector with respect to the second deflector, L 1 and L 2 are comatic aberration coefficients of the first and second deflectors, and C 1 , C 2 is defined as a chromatic aberration coefficient of the first and second deflectors, and L 3 and C 3 are defined with a rotation angle of the third deflector with respect to the second deflector being zero. The coma aberration coefficient and the chromatic aberration coefficient of the deflector are used, and u i2 and u i3 are respectively set to the second deflector, the rotation angle of the third deflector with respect to the second deflector being zero. It is defined as a beam incident position (complex number) on the objective lens image plane when a unit deflection voltage is applied to the third deflector, and θ = arg ((L 1 C 2 −L 2 C 1 ) / (L 3 C 1 −L 1 C 3 )), 0 <θ <2 arg (u i2 / u i3 ) or 0>θ> 2 arg (u i2 / u i3 It is preferable to select the distribution of the lens field and the deflection field so that the relationship of

また、前記第1の偏向器、前記第2の偏向器及び前記第3の偏向器の寸法、位置、相対的な回転角を調整して偏向場の分布を選び、これら3つの偏向器に入力する偏向信号を同じにすることが好ましい。   The distribution of the deflection field is selected by adjusting the size, position, and relative rotation angle of the first deflector, the second deflector, and the third deflector, and input to these three deflectors. It is preferable to make the deflection signals to be the same.

以上に説明したように、本願発明の荷電粒子ビーム装置は、3段の偏向器を連動させ、対物レンズ像面におけるビーム入射位置を決定しつつ偏向コマ収差と偏向色収差を同時に補正する装置であり、第1の偏向器を縮小レンズの前段あるいは対物レンズの物面付近に配置し、第2の偏向器を、その偏向場の全てあるいはその一部が対物レンズのレンズ場と重なるように配置する。さらに第3の偏向器を第2の偏向器の後段に配置する。   As described above, the charged particle beam device of the present invention is a device that simultaneously corrects the deflection coma aberration and the deflection chromatic aberration while determining the beam incident position on the image plane of the objective lens by interlocking the three-stage deflectors. The first deflector is arranged in front of the reduction lens or in the vicinity of the object surface of the objective lens, and the second deflector is arranged so that all or part of the deflection field overlaps the lens field of the objective lens. . Further, the third deflector is arranged at the subsequent stage of the second deflector.

第2、第3の偏向器への偏向電圧を同じにする。つまり、偏向電極への印加電圧を同じにする。   The same deflection voltage is applied to the second and third deflectors. That is, the applied voltage to the deflection electrode is made the same.

また、0<θ<2arg(ui2/ui3)あるいは0>θ>2arg(ui2/ui3)となるように、レンズ場と偏向場の分布を選択する。第3の偏向器を第2の偏向器に対して、第1、第2、第3の偏向器についての偏向コマ収差係数と偏向色収差係数から決まる角度θだけ回転させる。ui2とui3は、それぞれ、第3の偏向器の第2の偏向器に対する回転角を零にした状態で第2、第3偏向器に単位偏向電圧を印加したときの、対物レンズ像面におけるビーム入射位置である。 Further, the distribution of the lens field and the deflection field is selected so that 0 <θ <2 arg (u i2 / u i3 ) or 0>θ> 2 arg (u i2 / u i3 ). The third deflector is rotated with respect to the second deflector by an angle θ determined from the deflection coma aberration coefficient and the deflection chromatic aberration coefficient for the first, second, and third deflectors. u i2 and u i3 are objective lens image planes when a unit deflection voltage is applied to the second and third deflectors in a state where the rotation angle of the third deflector with respect to the second deflector is zero, respectively. Is the beam incident position.

本発明に係る荷電粒子ビーム装置は、電極長をあまり長くすることなく、電極内径をあまり小さくすることなく、かつ、偏向電圧をあまり高くすることなく、対物レンズ像面におけるビーム入射位置を決定しつつ偏向コマ収差と偏向色収差を同時に補正することができる。   The charged particle beam apparatus according to the present invention determines the beam incident position on the objective lens image plane without making the electrode length too long, without making the electrode inner diameter too small, and without making the deflection voltage too high. The deflection coma aberration and the deflection chromatic aberration can be corrected simultaneously.

以下、本発明を実施するための最良の形態について図面を参照しながら説明する。まず、第1の具体例について説明する。この第1の具体例は、電子ビームにより半導体製造に用いるフォトマスクのマスクパターンを描画する電子ビーム描画装置である。1mmの偏向フィールド内で、線幅1μm以下のパターンを描画する際に、nmオーダの精度での使用が要求される装置である。   The best mode for carrying out the present invention will be described below with reference to the drawings. First, a first specific example will be described. The first specific example is an electron beam drawing apparatus for drawing a mask pattern of a photomask used for semiconductor manufacturing by an electron beam. This apparatus is required to be used with an accuracy of the order of nm when drawing a pattern having a line width of 1 μm or less in a 1 mm deflection field.

図3は第1の具体例の電子描画装置の光学系を主体とした概略構成図である。この電子ビーム描画装置は、電子ビーム発生源2からの電子ビーム9の寸法を縮小する縮小レンズ1と、縮小レンズ1によって寸法が縮小された電子ビームを被ビーム照射物の表面に集束する対物レンズ4と、縮小レンズ4の前段に配置される第1の偏向器8と、対物レンズ4のレンズ場に対し、自らの発生する偏向場の全てあるいはその一部が重なるように配置される第2の偏向器7と、第2の偏向器7の後段に配置される第3の偏向器10とを備える。縮小レンズ1により光源(物体)2の像3が形成され、対物レンズ4により像3の像5が材料6面上に形成される。縮小レンズ1の倍率(絶対値)は当然1より小さいが、これは、微細な断面の電子ビーム(像5)を材料6に照射するためである。   FIG. 3 is a schematic block diagram mainly showing the optical system of the electronic drawing apparatus of the first specific example. This electron beam drawing apparatus includes a reduction lens 1 for reducing the size of an electron beam 9 from an electron beam generation source 2, and an objective lens for focusing the electron beam whose size is reduced by the reduction lens 1 on the surface of a beam irradiation object. 4, the first deflector 8 disposed in front of the reduction lens 4, and the second deflector disposed so that all or part of the deflection field generated by itself overlaps the lens field of the objective lens 4. , And a third deflector 10 disposed at the subsequent stage of the second deflector 7. An image 3 of the light source (object) 2 is formed by the reduction lens 1, and an image 5 of the image 3 is formed on the surface of the material 6 by the objective lens 4. The magnification (absolute value) of the reduction lens 1 is naturally smaller than 1, but this is because the material 6 is irradiated with an electron beam (image 5) having a fine cross section.

図4は電子描画装置の詳細な構成図である。電子ビーム発生源2から発生された電子ビームはブランキング機構13によりブランキングされる。ブランキング機構13は、ブランキング偏向器11とブランキングプレート12とからなる。   FIG. 4 is a detailed configuration diagram of the electronic drawing apparatus. The electron beam generated from the electron beam generation source 2 is blanked by the blanking mechanism 13. The blanking mechanism 13 includes a blanking deflector 11 and a blanking plate 12.

縮小レンズは電磁レンズ1であり、対物レンズも同じく電磁レンズ4である。材料6はステージ17上に載置される。ステージ17はステージ移動装置16により駆動される。   The reduction lens is the electromagnetic lens 1, and the objective lens is also the electromagnetic lens 4. Material 6 is placed on stage 17. The stage 17 is driven by a stage moving device 16.

制御装置14は、ステージ移動装置16にD/A変換器15を介してステージ移動信号を送る。また、制御装置21は、第1の偏向器8にD/A変換器20及びアンプ21を介してパターン描画位置データに対応する偏向信号を送る。また、制御装置14は、第2の偏向器7にD/A変換器18及びアンプ19を介してパターン描画位置データに対応する偏向信号を送る。また、制御装置14は、第3の偏向器10にD/A変換器18及びアンプ19を介してパターン描画位置データに対応する偏向信号を送る。第2の偏向器7及び第3の偏向器10用のアンプ19は共通のアンプである。また、D/A変換器18も共通のD/A変換器である。   The control device 14 sends a stage moving signal to the stage moving device 16 via the D / A converter 15. Further, the control device 21 sends a deflection signal corresponding to the pattern drawing position data to the first deflector 8 via the D / A converter 20 and the amplifier 21. Further, the control device 14 sends a deflection signal corresponding to the pattern drawing position data to the second deflector 7 via the D / A converter 18 and the amplifier 19. Further, the control device 14 sends a deflection signal corresponding to the pattern drawing position data to the third deflector 10 via the D / A converter 18 and the amplifier 19. The amplifier 19 for the second deflector 7 and the third deflector 10 is a common amplifier. The D / A converter 18 is also a common D / A converter.

この電子描画装置で特徴的なのは、第1の偏向器8が縮小レンズ1の前段に、第2、第3の偏向器7、10が後段に配置されていることである。   What is characteristic of this electronic drawing apparatus is that the first deflector 8 is disposed in the front stage of the reduction lens 1 and the second and third deflectors 7 and 10 are disposed in the subsequent stage.

また、第1の偏向器8、第2の偏向器7及び第3の偏向器10の寸法、位置、偏向電圧を調整して偏向場の分布を選び、像5の位置を決定しつつ各々の偏向器に起因する偏向コマ収差を互いに打ち消すと同時に、各々の偏向器に起因する偏向色収差を互いに打ち消す。   Further, the size, position, and deflection voltage of the first deflector 8, the second deflector 7, and the third deflector 10 are adjusted to select the distribution of the deflection field and determine the position of the image 5 while determining the position of the image 5. The deflection coma aberrations caused by the deflectors cancel each other, and the deflection chromatic aberrations caused by the respective deflectors cancel each other.

また、偏向コマ収差と偏向色収差が打ち消される条件を満たしつつ、第2の偏向器7及び第3の偏向器10に入力する偏向信号を同じにする。アンプ19を共通することによる。   Further, the deflection signals input to the second deflector 7 and the third deflector 10 are made the same while satisfying the conditions for canceling the deflection coma aberration and the deflection chromatic aberration. This is because the amplifier 19 is shared.

また、第3の偏向器10の第2の偏向器7に対する回転角(偏向電極の向き)θについて、前記第1及び第2の偏向器のコマ収差係数をL及びL、第1及び第2の偏向器の色収差をC及びCとし、第3の偏向器10の第2の偏向器7に対する回転角を零にした状態で定義される第3の偏向器10のコマ収差係数をL、第3の偏向器10の色収差係数をCとし、またui2とui3をそれぞれ第3の偏向器10の第2の偏向器7に対する回転角を零にした状態で、前記第2の偏向器7、前記第3の偏向器10に単位偏向電圧を印加したときの、前記対物レンズ4像面におけるビーム入射位置(複素数)と定義し、さらにθ=arg((L−L)/(L−L))としたとき、0<θ<2arg(ui2/ui3)あるいは0>θ>2arg(ui2/ui3)の関係が成り立つように、レンズ場と偏向場の分布を選択する。 Further, regarding the rotation angle (direction of the deflection electrode) θ of the third deflector 10 with respect to the second deflector 7, the coma aberration coefficients of the first and second deflectors are expressed as L 1 and L 2 , The coma aberration coefficient of the third deflector 10 defined with the chromatic aberration of the second deflector C 1 and C 2 and the rotation angle of the third deflector 10 with respect to the second deflector 7 is zero. L 3 , the chromatic aberration coefficient of the third deflector 10 is C 3, and u i2 and u i3 are set to be zero with the rotation angle of the third deflector 10 with respect to the second deflector 7 being zero. It is defined as a beam incident position (complex number) on the image plane of the objective lens 4 when a unit deflection voltage is applied to the second deflector 7 and the third deflector 10, and θ = arg ((L 1 C 2− L 2 C 1 ) / (L 3 C 1 −L 1 C 3 )), 0 <θ <2 arg (u i2 / u i3 ) Selects the distribution of the lens field and the deflection field so that the relationship 0>θ> 2arg (u i2 / u i3 ) is established.

また、第1の偏向器8、第2の偏向器7及び第3の偏向器10の寸法、位置、相対的な回転角を調整して偏向場の分布を選び、これら3つの偏向器に入力する偏向信号を同じにするようにしてもよい。   Further, the distribution of the deflection field is selected by adjusting the size, position, and relative rotation angle of the first deflector 8, the second deflector 7, and the third deflector 10, and input to these three deflectors. The deflection signals to be used may be the same.

以下、電子描画装置の動作について詳細に説明する。各偏向器の向き(X軸用偏向電極の向き)は、X軸に平行とする。   Hereinafter, the operation of the electronic drawing apparatus will be described in detail. The direction of each deflector (the direction of the X-axis deflection electrode) is parallel to the X-axis.

3つの偏向器8、7及び10を連動させたとき、偏向コマ収差と偏向色収差は、それぞれ重ね合わされて、式(1)、(2)と表される。

Figure 0004922747
Figure 0004922747
When the three deflectors 8, 7 and 10 are interlocked, the deflection coma aberration and the deflection chromatic aberration are superimposed and expressed as equations (1) and (2), respectively.
Figure 0004922747
Figure 0004922747

前記式(1)及び(2)にあって、式(3)と式(4)は光源2におけるビーム開き角(複素数)、LとR(光源2に近いほうからn=1,2,3)は各偏向器の偏向コマ収差係数(複素数)、Cは偏向色収差係数(複素数)である。

Figure 0004922747
Figure 0004922747
In the equations (1) and (2), the equations (3) and (4) are the beam opening angles (complex numbers) in the light source 2 and L n and R n (n = 1, 2 from the side closer to the light source 2). 3) is a deflection coma aberration coefficient (complex number) of each deflector, and C n is a deflection chromatic aberration coefficient (complex number).
Figure 0004922747
Figure 0004922747

またVは偏向電圧(複素数)で、式(5)と定義する。

Figure 0004922747
V n is a deflection voltage (complex number), which is defined as equation (5).
Figure 0004922747

nx、Vnyはそれぞれ各偏向器のX軸、Y軸用偏向電極への印加電圧である。ΔVは電子のエネルギー分散、V^は相対論補正を施した加速電圧である。連動する3つの偏向器に起因する偏向コマ収差が打ち消される条件式と、偏向色収差が打ち消される条件式は、それぞれ、式(6)、(7)となる。

Figure 0004922747
Figure 0004922747
V nx and V ny are applied voltages to the X-axis and Y-axis deflection electrodes of each deflector, respectively. ΔV is energy dispersion of electrons, and V 0 is an acceleration voltage subjected to relativity correction. The conditional expression for canceling the deflection coma aberration caused by the three interlocking deflectors and the conditional expression for canceling the deflection chromatic aberration are respectively Expressions (6) and (7).
Figure 0004922747
Figure 0004922747

コマ収差の性質から、Lの項が補正されると、自動的にRの項も補正されるため、式(6)の条件は簡単となり、式(8)となる。

Figure 0004922747
From the nature of coma aberration, when the term of L n is corrected, the term of R n is also automatically corrected, so the condition of equation (6) becomes simple and equation (8) is obtained.
Figure 0004922747

また、ここでは、偏向場の高次成分は無視している(XY面内の電界分布を均一としている)。すなわち、実用的には、各偏向器として、高次成分(6極子成分)を除去した8極あるいは12極の偏向器の使用を考えている。   Here, higher-order components of the deflection field are ignored (the electric field distribution in the XY plane is uniform). That is, practically, the use of an 8-pole or 12-pole deflector from which higher-order components (hexapole components) are removed is considered as each deflector.

通常はU’≠0かつΔV≠0であることより、式(7)、(8)を簡単にすれば、偏向コマ収差と偏向色収差が同時に打ち消される条件(偏向コマ・色収差同時補正条件)は、式(9)と表せる。この式(9)より、次の式(10)という関係が導ける。

Figure 0004922747
Figure 0004922747
Usually, U 0 ′ ≠ 0 and ΔV ≠ 0, so that the equations (7) and (8) can be simplified to cancel the deflection coma aberration and the deflection chromatic aberration at the same time (deflection coma and chromatic aberration simultaneous correction condition). Can be expressed as Equation (9). From this equation (9), the following equation (10) can be derived.
Figure 0004922747
Figure 0004922747

ここで、A及びAは式(11)という関係である。

Figure 0004922747
Here, A 1 and A 3 have the relationship of Expression (11).
Figure 0004922747

3つの偏向器を連動させたとき、材料6面上における像5の位置(複素数)は、式(12)と表せる。

Figure 0004922747
When the three deflectors are interlocked, the position (complex number) of the image 5 on the surface of the material 6 can be expressed by Expression (12).
Figure 0004922747

この式(12)にあって、uinは各偏向器に単位電圧V=1V(Vnx=1V、Vny=0V)を印加したときの、材料6面上における像5の位置(複素数)を示す。 In this equation (12), u in is the position (complex number) of the image 5 on the surface of the material 6 when the unit voltage V n = 1V (V nx = 1V, V ny = 0V) is applied to each deflector. ).

第2、第3の偏向器7、10のいずれか、あるいは両方は、位置決めの役割を担うから、|V|と|V|のいずれかあるいは両方は、両偏向器を駆動する高速アンプの出力の許す限り十分大きく設定されている(偏向器へのコンタミ付着・帯電をできるだけ防ぐ目的で、偏向器内径をできるだけ大きくしている)。また、第1の偏向器8は第2、第3の偏向器7、10と連動するため、第1の偏向器8の偏向速度も、第2、第3の偏向器7、10のそれと同等でなければならないから、第1の偏向器8も、第2、第3の偏向器7、10と同様に高速アンプで駆動される。これらの理由から、|V|>|V|や|V|>|V|となることは通常ない。また、第1の偏向器8は縮小レンズ1の前段(あるいは対物レンズ4の物面近くでもよい)にあり、第2、第3の偏向器7、10は対物レンズ4の物面より後段にあることから、|ui1|は、|ui2|および|ui3|に比べて小さい。以上の理由から、|ui1|は|ui2|および|ui3|に比べ十分小さい。従って、式(12)において、ui1を無視すれば、改めて、式(13)と表せる。

Figure 0004922747
Since either or both of the second and third deflectors 7 and 10 play a role of positioning, either or both of | V 2 | and | V 3 | is a high-speed amplifier that drives both deflectors. Is set as large as allowed by the output of the output (in order to prevent contamination and charging to the deflector as much as possible, the inner diameter of the deflector is made as large as possible). In addition, since the first deflector 8 is interlocked with the second and third deflectors 7 and 10, the deflection speed of the first deflector 8 is equivalent to that of the second and third deflectors 7 and 10. Therefore, the first deflector 8 is also driven by a high-speed amplifier in the same manner as the second and third deflectors 7 and 10. For these reasons, | V 1 |> | V 2 | and | V 1 |> | V 3 | The first deflector 8 is in the front stage of the reduction lens 1 (or may be near the object surface of the objective lens 4), and the second and third deflectors 7 and 10 are in the rear stage from the object surface of the objective lens 4. Therefore, | u i1 | is smaller than | u i2 | and | u i3 |. For the above reasons, | u i1 V 1 | is sufficiently smaller than | u i2 V 2 | and | u i3 V 3 |. Therefore, in the equation (12), if u i1 V 1 is ignored, it can be expressed again as the equation (13).
Figure 0004922747

第2、第3の偏向器7、10を分割する前(偏向コマ収差と偏向色収差のいずれかを補正する、あるいは補正をしない)は、V=Vとなるから、偏向器分割前の、材料6面上における像5の位置をUicと表すと、式(13)を用いて、以下の式(14)となる。

Figure 0004922747
Before the second and third deflectors 7 and 10 are divided (either the deflection coma aberration or the deflection chromatic aberration is corrected or not corrected), V 2 = V 3 . When the position of the image 5 on the surface of the material 6 is expressed as U ic , the following expression (14) is obtained using the expression (13).
Figure 0004922747

一方、偏向器分割後(偏向コマ収差と偏向色収差を同時に補正する)の像5の位置は、式(10)と式(13)から、以下の式(15)となる。

Figure 0004922747
On the other hand, the position of the image 5 after dividing the deflector (correcting the deflection coma aberration and the deflection chromatic aberration at the same time) is expressed by the following expression (15) from the expressions (10) and (13).
Figure 0004922747

ここで、A=|A|exp(iθ)と表すと、式(16)となる。

Figure 0004922747
Here, when expressed as A 3 = | A 3 | exp (iθ), Expression (16) is obtained.
Figure 0004922747

この式(16)は、第3の偏向器10を機械的に第2の偏向器7に対してθだけ回転させ、第3の偏向器10の偏向電圧を|A|倍に高めたときの、材料6面上における像5の位置と解釈できる。すなわち、電気的にAの向きを変えることは、機械的にAの向きを変えることと等価である。UicとUを図5に示す。 This equation (16) is obtained when the third deflector 10 is mechanically rotated by θ with respect to the second deflector 7 and the deflection voltage of the third deflector 10 is increased by | A 3 | Can be interpreted as the position of the image 5 on the surface of the material 6. That is, electrically changing the direction of A 3 is equivalent to changing the direction of mechanically A 3. U ic and U i are shown in FIG.

の向きを変えるには、3つの偏向器を、相対的な回転角を保って回転させればよいから、Uを議論するうえでは、その大きさ|U|に着目すればよい。そこで、以下で、|Ui|ができるだけ大きくなる条件について議論する。同じ偏向電圧に対して|U|ができるだけ大きくなる条件は、同じ|U|に対して偏向電圧ができるだけ低くなる条件と等価であるから、そのような条件を求めれば、本発明の目的を達成することができる。 To change the orientation of the U i, the three deflectors, since it is sufficient to rotate while maintaining a relative rotation angle, in order to discuss the U i, the magnitude | may be paying attention to | U i . Therefore, in the following, the conditions under which | Ui | becomes as large as possible will be discussed. The condition that | U i | becomes as large as possible with respect to the same deflection voltage is equivalent to the condition that the deflection voltage becomes as low as possible with respect to the same | U i |. Can be achieved.

式(16)と図5から分かるように、|U|を大きくするには、|arg(ui3/ui2)+θ|をできるだけ小さく、かつ、|A|を大きくすればよい。しかし、先述のように、|V|は既に十分大きく設定されているため、|A|>1にはできない。従って、|A|=1とするのが最もよい。また、|A|=1の状態で第3の偏向器10を機械的に第2の偏向器7に対してθだけ回転させれば、A=1にすることができるから、両偏向器に同じ偏向信号が入力できる、すなわち、両偏向器が同じアンプ19やDA変換器18で駆動・制御できるという利点も生じる。 As can be seen from Equation (16) and FIG. 5, in order to increase | U i |, | arg (u i3 / u i2 ) + θ | should be as small as possible and | A 3 | However, as described above, | V 2 | has already been set sufficiently large, so | A 3 |> 1 cannot be established. Therefore, it is best to set | A 3 | = 1. Further, if the third deflector 10 is mechanically rotated by θ with respect to the second deflector 7 in the state of | A 3 | = 1, A 3 = 1 can be obtained. There is also an advantage that the same deflection signal can be input to the device, that is, both the deflectors can be driven and controlled by the same amplifier 19 and DA converter 18.

|ui2|と|ui3|は各偏向器を回転させても変わらないから、|A|=1に固定するならば、|U|と|Uic|は、ui2とui3のなす角度arg(ui3/ui2)で決まる。|U|<|Uic|では、必要な偏向電圧が偏向器分割前より高くなってしまうから、少なくとも|U|>|Uic|となるようにL,R,C(n=1,2,3)を選択する、すなわちレンズ場と偏向場の分布を決定するとよい。図5より、|U|>|Uic|となる条件は、
arg(ui3/ui2)<arg(ui3/ui2)+θ<−arg(ui3/ui2
すなわち、0<θ<2arg(ui2/ui3)である(arg(ui2/ui3)=−arg(ui3/ui2))。このとき、第3の偏向器10の、第2の偏向器7に対する回転の向きは、レンズ磁場により電子ビーム9の軌道が回転する向きに一致する。また、θ=arg(ui2/ui3)のとき、|U|は最大となる。
Since | u i2 | and | u i3 | do not change even if each deflector is rotated, if | A 3 | = 1 is fixed, | U i | and | U ic | are equal to u i2 and u i3. Is determined by the angle arg (u i3 / u i2 ) formed by In | U i | <| U ic |, the necessary deflection voltage becomes higher than that before the deflector division, so that at least | U i |> | U ic |, L n , R n , C n ( n = 1, 2, 3), that is, the distribution of the lens field and the deflection field should be determined. From FIG. 5, the condition of | U i |> | U ic |
arg (u i3 / u i2 ) <arg (u i3 / u i2 ) + θ <−arg (u i3 / u i2 )
That is, 0 <θ <2arg (u i2 / u i3) (arg (u i2 / u i3) = - arg (u i3 / u i2)). At this time, the rotation direction of the third deflector 10 relative to the second deflector 7 coincides with the rotation direction of the electron beam 9 by the lens magnetic field. Also, when θ = arg (u i2 / u i3 ), | U i | is maximized.

なお、ここでは、レンズ磁場により電子ビーム9の軌道が回転する向きは、電子の進行とともに右回り(右ねじの向き。図4では反時計回り)を仮定しているが、もし軌道の回転する向きが逆であれば、上の条件は、
arg(ui3/ui2)>arg(ui3/ui2)+θ>−arg(ui3/ui2
すなわち、0>θ>2arg(ui2/ui3)となる。
Here, the direction in which the orbit of the electron beam 9 is rotated by the lens magnetic field is assumed to be clockwise (the direction of the right-handed screw, counterclockwise in FIG. 4) as the electron travels. If the direction is reversed, the above condition is
arg (u i3 / u i2 )> arg (u i3 / u i2 ) + θ> −arg (u i3 / u i2 )
That is, 0>θ> 2arg (u i2 / u i3 ).

上の例では、第2の偏向器7と第3の偏向器10の間に間隙はないものとしているが、偏向器を分割して回転させるならば、実際には、絶縁のため、両者間には間隙を設ける必要がある。さらには、偏向電極や、電界遮蔽用の棒状体(例えば特開平2−100250参照)を支持するため、分割した偏向器の間には板状の支持体が必要になるから、この分、間隙は大きくしなくてはならない。   In the above example, it is assumed that there is no gap between the second deflector 7 and the third deflector 10. However, if the deflector is divided and rotated, it is actually between the two for insulation. It is necessary to provide a gap. Furthermore, a plate-like support is required between the divided deflectors to support the deflection electrode and the bar for electric field shielding (see, for example, JP-A-2-100250). Must be bigger.

空間的制約から、第2の偏向器7の上端と、第3の偏向器10の下端の位置を変えないものとすると、この間隙のため、(合計した)偏向器長は分割前より短くならざるをえない。すなわち、偏向器を分割すると、偏向器長の減少分だけ|U|が小さくなる。0<θ<2arg(ui2/ui3)(あるいは0>θ>2arg(ui2/ui3))となるようにL,R,C(n=1,2,3)を選ぶ、すなわちレンズ場と偏向場の分布を選ぶ際には、この減少分の補償を考慮するとよい。 If the position of the upper end of the second deflector 7 and the position of the lower end of the third deflector 10 are not changed due to space constraints, the (total) deflector length becomes shorter than before the division because of this gap. I cannot help it. That is, if the deflector is divided, | U i | becomes smaller by the decrease of the deflector length. L n , R n , C n (n = 1, 2, 3) are selected so that 0 <θ <2 arg (u i2 / u i3 ) (or 0>θ> 2 arg (u i2 / u i3 )). That is, when selecting the distribution of the lens field and the deflection field, compensation for this decrease should be taken into consideration.

なお、先述のように、収差補正用偏向器の偏向電圧を下げるには、その偏向器を縮小レンズ1の前段に配置することが有効であるが、縮小レンズ1の前段に第1、第2の偏向器8、7の両方を配置(第3の偏向器10は縮小レンズ1の後段に配置)すると、次のような問題が生じる。第1、第2の偏向器8、7をこのように配置すると、両偏向器の収差特性は近くなる。より具体的にいえば、両者の偏向コマ収差と偏向色収差の比が近くなり、L/C=L/Cに近い状態となる。これは、縮小レンズ1の前段の偏向器により電子ビーム9を偏向する場合、光源2の像3の、縮小レンズ1の像面上における位置が、縮小レンズ1の倍率の低さから、その偏向器の寸法や位置にあまり依存しない、すなわち、縮小レンズ1のレンズ場を通過後の偏向軌道の形状が(軌道の、中心軸からの距離は変わるが)、その偏向器の寸法や位置にあまり依存しないためである。偏向コマ収差と偏向色収差を同時に補正するならば、式(10)よりV=V/Aとしなくてはいけないが、L/C=L/CすなわちL−L=0に近い状態になると、Aが零に近づき、その結果|V|>>|V|となる。 As described above, in order to lower the deflection voltage of the aberration correcting deflector, it is effective to dispose the deflector in front of the reducing lens 1, but the first and second in front of the reducing lens 1 are effective. When both of the deflectors 8 and 7 are disposed (the third deflector 10 is disposed at the rear stage of the reduction lens 1), the following problem occurs. When the first and second deflectors 8 and 7 are arranged in this manner, the aberration characteristics of both deflectors become close to each other. More specifically, the ratio between the deflection coma aberration and the deflection chromatic aberration becomes close to L 1 / C 1 = L 2 / C 2 . This is because, when the electron beam 9 is deflected by a deflector in front of the reduction lens 1, the position of the image 3 of the light source 2 on the image plane of the reduction lens 1 is deflected because the magnification of the reduction lens 1 is low. The shape of the deflection trajectory after passing through the lens field of the reduction lens 1 (although the distance from the central axis of the trajectory varies) is not very dependent on the size and position of the deflector. It is because it does not depend. If the deflection coma aberration and the deflection chromatic aberration are corrected at the same time, V 2 = V 3 / A 3 must be obtained from the equation (10), but L 1 / C 1 = L 2 / C 2, that is, L 1 C 2 − When close to L 2 C 1 = 0, A 3 approaches zero, resulting in | V 2 | >> | V 3 |.

第3の偏向器10には位置決めの役割を担わせるから十分に高い偏向電圧を印加するが、第2の偏向器7にはさらに高い偏向電圧を印加する必要があることを、この関係は示している。また、|A|<<1でない限り、|V|>|V|となりうる。しかし、偏向速度の要求から、|V|>|V|や|V|>|V|とすることはできないから、このような配置を避けなければならない。同じ理由から、縮小レンズ1の前段に第1の偏向器8を、かつ対物レンズ4の物面(縮小レンズ1の像面)付近に第2の偏向器7を配置する、あるいは、対物レンズ4の物面付近に第1、第2の偏向器8、7の両方を配置するのも避けるのがよい。 This relationship indicates that a sufficiently high deflection voltage is applied to the third deflector 10 because it plays a role of positioning, but a higher deflection voltage needs to be applied to the second deflector 7. ing. Further, as long as | A 1 | << 1, it can be | V 1 | >> | V 3 |. However, since it is not possible to set | V 2 |> | V 3 | or | V 1 |> | V 3 | due to the requirement of the deflection speed, such an arrangement must be avoided. For the same reason, the first deflector 8 is disposed in front of the reduction lens 1 and the second deflector 7 is disposed in the vicinity of the object surface of the objective lens 4 (image surface of the reduction lens 1), or the objective lens 4. It is also preferable to avoid disposing both the first and second deflectors 8 and 7 near the object surface.

逆に、第1、第2の偏向器8、7の収差特性に差を持たせる、すなわち、L/C=L/Cに近い状態を避けるには、第1の偏向器8を縮小レンズ1の前段、あるいは対物レンズ4の物面(縮小レンズ1の像面)の近傍に配置するのに対し、第2の偏向器7を図3に示すように対物レンズ4のレンズ場内に配置する(少なくとも、第2の偏向器7による偏向場の一部が対物レンズ4のレンズ場と重なるように配置する)のがよい。偏向収差は、偏向器により電子ビーム9の軌道が曲げられ、その軌道のレンズ中心軸からのずれがレンズ場内において大きくなることにより増加するから、軌道の曲がり始めの位置を変えることで、収差の増加する区間を変えることができ、その結果、偏向器の収差特性(偏向コマ収差と偏向色収差の比)が変わる。 Conversely, in order to make a difference in the aberration characteristics of the first and second deflectors 8 and 7, that is, to avoid a state close to L 1 / C 1 = L 2 / C 2 , the first deflector 8 Is disposed in front of the reduction lens 1 or in the vicinity of the object plane of the objective lens 4 (image plane of the reduction lens 1), whereas the second deflector 7 is disposed in the lens field of the objective lens 4 as shown in FIG. (At least a part of the deflection field by the second deflector 7 is arranged so as to overlap the lens field of the objective lens 4). The deflection aberration increases when the trajectory of the electron beam 9 is bent by the deflector, and the deviation of the trajectory from the lens center axis increases in the lens field. The increasing interval can be changed, and as a result, the aberration characteristics of the deflector (ratio of deflection coma and deflection chromatic aberration) change.

以上のような光学系配置、動作条件により、偏向電圧を高くすることなく、また、偏向器長を長くしたり偏向器内径を小さくしたりすることなく、像5の位置を決定しつつ偏向コマ収差と偏向色収差を同時に補正することが可能になる。   Due to the arrangement and operating conditions of the optical system as described above, the deflection frame is determined while determining the position of the image 5 without increasing the deflection voltage, and without increasing the deflector length or reducing the deflector inner diameter. Aberration and deflection chromatic aberration can be corrected simultaneously.

なお、先述のように、第3の偏向器10を機械的に第2の偏向器7に対してθだけ回転させ、A=1とすることで、両偏向器が同じアンプやDA変換器で駆動・制御できるが、これを押し進め、第1の偏向器8の寸法、位置、回転角を選び、3つの偏向器全てについて偏向電圧を等しくする(A=A=1)と、全ての偏向器が同じアンプやDA変換器で駆動・制御できるようになる。 As described above, the third deflector 10 is mechanically rotated by θ with respect to the second deflector 7 so that A 3 = 1, so that both deflectors have the same amplifier or DA converter. This can be driven and controlled by selecting the size, position and rotation angle of the first deflector 8 and making the deflection voltages equal for all three deflectors (A 1 = A 3 = 1). Can be driven and controlled by the same amplifier or DA converter.

偏向コマ・色収差同時補正において0<θ<2arg(u i2 /u i3 (あるいは0>θ>2arg(ui2/ui3))となるような条件が実際に存在することを示すため、図3の光学系のように3段の偏向器を用いた集束偏向系について収差補正シミュレーションを実施した。縮小レンズ1のレンズ場分布は固定とし、対物レンズ4のレンズ場分布と偏向場分布を変えて計算を行った。対物レンズ4のレンズ場分布と偏向場分布は仮想的なものとし、解析関数の重ね合わせで表した。ただし、偏向電圧に対する偏向場の強さは、十分な偏向器長の、偏向器内径9mmの偏向器に対する数値計算結果に合わせた。各偏向器の長さは、|A|=|A|=1となるように選んだ。第2の偏向器7の上端と、第3の偏向器10の下段の位置は変えないものとし、両偏向器間の間隙は3mmとした。光源2の位置と材料6面の位置はそれぞれz=−220mm、0mmとし、投影倍率は1/20とした。 In order to show that there is actually a condition such that 0 <θ <2arg (u i2 / u i3 ) (or 0>θ> 2arg (u i2 / u i3 )) in the simultaneous correction of deflection coma and chromatic aberration, Aberration correction simulation was performed on a focusing deflection system using a three-stage deflector like the three optical systems. Calculation was performed with the lens field distribution of the reduction lens 1 fixed and the lens field distribution and deflection field distribution of the objective lens 4 changed. The lens field distribution and the deflection field distribution of the objective lens 4 are assumed to be virtual and are represented by superposition of analysis functions. However, the strength of the deflection field with respect to the deflection voltage was matched with the numerical calculation result for a deflector having a sufficient deflector length and an inner diameter of 9 mm. The length of each deflector was chosen to be | A 1 | = | A 3 | = 1. The position of the upper end of the second deflector 7 and the lower position of the third deflector 10 were not changed, and the gap between both deflectors was 3 mm. The positions of the light source 2 and the material 6 are z = −220 mm and 0 mm, respectively, and the projection magnification is 1/20.

シミュレーションで得られた結果を表1、図6に示す。表1は、計算で得られたui2、ui3、2arg(ui2/ui3)、θ、偏向電圧の値を示す。図6は、レンズ場と偏向場の強度分布を示す。縦軸は磁界強度と電界強度の大きさを示す。横軸は位置z[mm]を示す。比較のため、対物レンズ4のレンズ場を変えた2つの光学系(a)、(b)について結果を示してある。

Figure 0004922747
The results obtained by the simulation are shown in Table 1 and FIG. Table 1 shows the values of u i2 , u i3 , 2 arg (u i2 / u i3 ), θ, and deflection voltage obtained by calculation. FIG. 6 shows the intensity distribution of the lens field and the deflection field. The vertical axis indicates the magnitude of the magnetic field strength and electric field strength. The horizontal axis indicates the position z [mm]. For comparison, the results are shown for two optical systems (a) and (b) in which the lens field of the objective lens 4 is changed.
Figure 0004922747

表1に示す偏向電圧は、材料6面上における像5のXおよびY方向への500μm移動つまりX軸から45°方向への707μm(=500×√2)移動に対するものである。   The deflection voltage shown in Table 1 is for 500 μm movement of the image 5 in the X and Y directions on the surface of the material 6, that is, 707 μm (= 500 × √2) movement in the 45 ° direction from the X axis.

偏向器分割前の偏向電圧を比較すると、両光学系の偏向電圧は155V前後であり、ほとんど差はない。しかし、偏向器分割後は両者に大きな差が生じている。偏向器分割後、光学系aでは、0<θ<2arg(ui2/ui3)となっており、その偏向電圧は、(第2、第3の偏向器7、10間に間隙があるにもかかわらず)155Vと、偏向器分割前の偏向電圧157Vより低くなっている。一方、光学系bでは、0<2arg(ui2/ui3)<θとなっており、その偏向電圧は210Vと、偏向器分割前の偏向電圧154Vより大幅に高くなっている。 Comparing the deflection voltages before dividing the deflectors, the deflection voltages of both optical systems are around 155 V, and there is almost no difference. However, there is a large difference between the two after dividing the deflector. After dividing the deflector, in the optical system a, 0 <θ <2arg (u i2 / u i3 ), and the deflection voltage is (there is a gap between the second and third deflectors 7 and 10). Regardless, 155V, which is lower than the deflection voltage 157V before the deflector division. On the other hand, in the optical system b, 0 <2arg (u i2 / u i3 ) <θ, and the deflection voltage is 210 V, which is significantly higher than the deflection voltage 154 V before the deflector division.

次に、第2の具体例について説明する。この第2の具体例も電子描画装置である。図7は、第2の具体例の電子描画装置の光学系を主体とした概略構成図である。第2の具体例が第1の具体例と異なるのは、第1の偏向器8の配置である。第1の偏向器8を、縮小レンズ1の近傍に置いている。詳細には、縮小レンズ1と第2の偏向器7との間であって、像3の付近である。   Next, a second specific example will be described. This second specific example is also an electronic drawing apparatus. FIG. 7 is a schematic configuration diagram mainly including the optical system of the electronic drawing apparatus of the second specific example. The second specific example is different from the first specific example in the arrangement of the first deflector 8. The first deflector 8 is placed in the vicinity of the reduction lens 1. Specifically, it is between the reduction lens 1 and the second deflector 7 and in the vicinity of the image 3.

動作としては、前記第1の具体例と同様であるので説明を省略する。   Since the operation is the same as that of the first specific example, description thereof is omitted.

次に、第3の具体例について説明する。この第3の具体例は、電子ビームの代わりに、イオンビームなどの荷電粒子ビームを用いる。構成及び動作は、前記第1具体例および第2具体例と同様である。   Next, a third specific example will be described. In the third specific example, a charged particle beam such as an ion beam is used instead of the electron beam. The configuration and operation are the same as those of the first specific example and the second specific example.

以上に説明したように、前記第1〜第3具体例によれば、3段の偏向器を連動させ、偏向コマ収差と偏向色収差を同時に補正する荷電粒子ビーム集束偏向装置において、第1の偏向器を縮小レンズの前段あるいは対物レンズの物面付近に配置し、第2の偏向器を、その偏向場の全てあるいはその一部が対物レンズのレンズ場と重なるように配置する。さらに第3の偏向器を第2の偏向器の後段に配置する。   As described above, according to the first to third specific examples, in the charged particle beam focusing deflection apparatus that simultaneously corrects the deflection coma aberration and the deflection chromatic aberration by interlocking the three-stage deflector, the first deflection is performed. And the second deflector is arranged so that all or part of the deflection field thereof overlaps the lens field of the objective lens. Further, the third deflector is arranged at the subsequent stage of the second deflector.

第2、第3の偏向器への偏向電圧を同じにする。これは偏向電極への印加電圧を同じにすることである。つまり、偏向器駆動アンプを一つにする。   The same deflection voltage is applied to the second and third deflectors. This is to make the applied voltages to the deflection electrodes the same. That is, one deflector driving amplifier is used.

0<θ<2arg(ui2/ui3)あるいは0>θ>2arg(ui2/ui3)となるように、レンズ場と偏向場の分布を選択する。第3の偏向器を第2の偏向器に対して、第1,2,3の偏向器についての偏向コマ収差係数と偏向色収差係数から決まる角度θだけ回転させる。ui2とui3は、それぞれ、第3の偏向器の第2の偏向器に対する回転角を零にした状態で第2、第3偏向器に単位偏向電圧を印加したときの、対物レンズ像面におけるビーム入射位置である。 The distribution of the lens field and the deflection field is selected so that 0 <θ <2 arg (u i2 / u i3 ) or 0>θ> 2 arg (u i2 / u i3 ). The third deflector is rotated relative to the second deflector by an angle θ determined from the deflection coma aberration coefficient and the deflection chromatic aberration coefficient for the first, second, and third deflectors. u i2 and u i3 are objective lens image planes when a unit deflection voltage is applied to the second and third deflectors in a state where the rotation angle of the third deflector with respect to the second deflector is zero, respectively. Is the beam incident position.

これらの工夫により電極長をあまり長くすることなく、電極内径をあまり小さくすることなく、かつ、偏向電圧をあまり高くすることなく、対物レンズ像面におけるビーム入射位置を決定しつつ偏向コマ収差と偏向色収差を同時に補正することができる。   With these devices, the deflection coma aberration and deflection can be determined while determining the beam incident position on the objective lens image plane without making the electrode length too long, making the electrode inner diameter too small, and making the deflection voltage too high. Chromatic aberration can be corrected simultaneously.

なお、図4に示した詳細な構成は、第2実施例及び第3実施例にも適用できる。また、いずれの実施例にあっても、第2の偏向器7及び第3の偏向器10のアンプ19及D/A変換器18を共通とし、偏向電極への印加電圧を同じにできる。また、第1の偏向器8に接続するアンプ21及びD/A変換器20を、前記第2の偏向器7及び第3の偏向器10のアンプ19及D/A変換器18と共通にしてもよい。   The detailed configuration shown in FIG. 4 can also be applied to the second and third embodiments. In any of the embodiments, the amplifier 19 and the D / A converter 18 of the second deflector 7 and the third deflector 10 are made common, and the applied voltage to the deflection electrode can be made the same. Further, the amplifier 21 and the D / A converter 20 connected to the first deflector 8 are made common with the amplifier 19 and the D / A converter 18 of the second deflector 7 and the third deflector 10. Also good.

従来の電子ビーム描画装置の一概略例である。It is a schematic example of the conventional electron beam drawing apparatus. 収差補正用偏向器を縮小レンズの前段に配置した電子ビーム描画装置の一概略例である。1 is a schematic example of an electron beam drawing apparatus in which an aberration correcting deflector is arranged in front of a reduction lens. 本発明の第1の具体例となる、電子ビーム描画装置の一概略例である。1 is a schematic example of an electron beam drawing apparatus as a first specific example of the present invention. 本発明の電子ビーム描画装置の詳細な構成例である。1 is a detailed configuration example of an electron beam drawing apparatus according to the present invention. 材料6面上の像5の位置(電子ビーム入射位置)を示す図である。It is a figure which shows the position (electron beam incident position) of the image 5 on the material 6 surface. レンズ場と偏向場の強度分布を示す図である。It is a figure which shows intensity distribution of a lens field and a deflection field. 第2の実施例となる、電子ビーム描画装置の一概略例である。2 is a schematic example of an electron beam drawing apparatus according to a second embodiment.

符号の説明Explanation of symbols

1 縮小レンズ
2 電子ビーム源
3 像
4 対物レンズ
5 像
6 材料
7 第2の偏向器
8 第1の偏向器
9 電子ビーム
10 第3の偏向器
DESCRIPTION OF SYMBOLS 1 Reduction lens 2 Electron beam source 3 Image 4 Objective lens 5 Image 6 Material 7 2nd deflector 8 1st deflector 9 Electron beam 10 3rd deflector

Claims (3)

荷電粒子ビームを発生する荷電粒子ビーム源と、前記荷電粒子ビーム源からの荷電粒子ビームの寸法を縮小する縮小レンズと、前記縮小レンズによって寸法が縮小された荷電粒子ビームを被ビーム照射物の表面に集束する対物レンズと、前記縮小レンズの前段或いは前記対物レンズの物面近傍に配置される第1の偏向器と、前記対物レンズのレンズ場に対し、自らの発生する偏向場の全てあるいはその一部が重なるように配置される第2の偏向器と、前記第2の偏向器の後段に配置される第3の偏向器とを備えた荷電粒子ビーム装置において、
前記第1の偏向器のコマ収差係数(複素数)をL 、前記第2の偏向器のコマ収差係数(複素数)をL 、前記第1の偏向器の色収差係数(複素数)をC 、前記第2の偏向器の色収差係数(複素数)をC 、前記第3の偏向器の前記第2の偏向器に対する偏向電極の回転角を零にした状態の第3の偏向器のコマ収差係数(複素数)をL 、前記状態の前記第3の偏向器の色収差係数(複素数)をC
前記第2の偏向器に単位偏向電圧を印加したときの前記対物レンズ像面におけるビーム入射位置(複素数)をu i2
前記第3の偏向器の前記第2の偏向器に対する偏向電極の回転角を零にした状態で前記第3の偏向器に単位偏向電圧を印加したときの前記対物レンズ像面におけるビーム入射位置(複素数)をu i3 としたとき、
前記第3の偏向器を前記第2の偏向器に対して角度θだけ回転させ、該角度θを
θ=arg((L −L )/(L −L ))としたとき、
前記対物レンズのレンズ場により前記荷電粒子ビームの軌道が回転する向きが右回りの場合、
0<θ<2arg(u i2 /u i3 )
の条件を満たし、または、
前記対物レンズのレンズ場により前記荷電粒子ビームの軌道が回転する向きが左回りの場合、
0>θ>2arg(u i2 /u i3 )
の条件を満たすことを特徴とする荷電粒子ビーム装置。
A charged particle beam source for generating a charged particle beam; a reduction lens for reducing the size of the charged particle beam from the charged particle beam source; and a charged particle beam whose size is reduced by the reduction lens; An objective lens that converges on the objective lens, a first deflector disposed in front of the reduction lens or in the vicinity of the object surface of the objective lens, and a deflection field generated by itself with respect to the lens field of the objective lens , or In a charged particle beam apparatus comprising a second deflector arranged so that a part thereof overlaps and a third deflector arranged after the second deflector ,
The coma aberration coefficient (complex number) of the first deflector is L 1 , the coma aberration coefficient (complex number) of the second deflector is L 2 , and the chromatic aberration coefficient (complex number) of the first deflector is C 1 , The chromatic aberration coefficient (complex number) of the second deflector is C 2 , and the coma aberration coefficient of the third deflector in a state where the rotation angle of the deflection electrode with respect to the second deflector of the third deflector is zero. (Complex number) is L 3 , and the chromatic aberration coefficient (complex number) of the third deflector in the state is C 3 ,
A beam incident position (complex number) on the objective lens image plane when a unit deflection voltage is applied to the second deflector, u i2 ,
A beam incident position on the image plane of the objective lens when a unit deflection voltage is applied to the third deflector in a state where a rotation angle of a deflection electrode of the third deflector with respect to the second deflector is zero. (Complex number) is u i3 ,
The third deflector is rotated with respect to the second deflector by an angle θ, and the angle θ is
When θ = arg ((L 1 C 2 -L 2 C 1 ) / (L 3 C 1 -L 1 C 3 )),
When the direction in which the trajectory of the charged particle beam rotates by the lens field of the objective lens is clockwise,
0 <θ <2arg (u i2 / u i3 )
Meets the requirements of
When the direction in which the trajectory of the charged particle beam rotates by the lens field of the objective lens is counterclockwise,
0>θ> 2arg (u i2 / u i3 )
A charged particle beam device characterized by satisfying the following conditions .
前記第2の偏向器及び前記第3の偏向器に同一の偏向信号を入力することを特徴とする請求項1記載の荷電粒子ビーム装置。 The charged particle beam apparatus according to claim 1, wherein the same deflection signal is input to the second deflector and the third deflector . 前記第1の偏向器、前記第2の偏向器及び前記第3の偏向器に同一の偏向信号を入力することを特徴とする請求項記載の荷電粒子ビーム装置。 Said first deflector, the second deflector and a charged particle beam apparatus according to claim 1, wherein the inputting identical deflection signals to said third deflector.
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